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Chemical and Mechanical Tunability of 3D-Printed Dynamic Covalent Networks Based on Boronate Esters

As the scope of additive manufacturing broadens, interest has developed in 3D-printed objects that are derived from recyclable resins with chemical and mechanical tunability. Dynamic covalent bonds have the potential to not only increase the sustainability of 3D-printed objects, but also serve as re...

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Published in:	ACS macro letters 2021-07, Vol.10 (7), p.857-863
Main Authors:	Robinson, Lindsay L, Self, Jeffrey L, Fusi, Alexander D, Bates, Morgan W, Read de Alaniz, Javier, Hawker, Craig J, Bates, Christopher M, Sample, Caitlin S
Format:	Article
Language:	English
Subjects:	Esters Materials Testing Printing, Three-Dimensional Resins, Plant
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cited_by	cdi_FETCH-LOGICAL-a348t-9573c931dc0d2b6a9f103889227892c8e337147569c678cf34e790f26807afe63
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creator	Robinson, Lindsay L Self, Jeffrey L Fusi, Alexander D Bates, Morgan W Read de Alaniz, Javier Hawker, Craig J Bates, Christopher M Sample, Caitlin S
description	As the scope of additive manufacturing broadens, interest has developed in 3D-printed objects that are derived from recyclable resins with chemical and mechanical tunability. Dynamic covalent bonds have the potential to not only increase the sustainability of 3D-printed objects, but also serve as reactive sites for postprinting derivatization. In this study, we use boronate esters as a key building block for the development of catalyst-free, 3D-printing resins with the ability to undergo room-temperature exchange at the cross-linking sites. The orthogonality of boronate esters is exploited in fast-curing, oxygen-tolerant thiol–ene resins in which the dynamic character of 3D-printed objects can be modulated by the addition of a static, covalent cross-linker with no room-temperature bond exchange. This allows the mechanical properties of printed parts to be varied between those of a traditional thermoset and a vitrimer. Objects printed with a hybrid dynamic/static resin exhibit a balance of structural stability (residual stress = 18%) and rapid exchange (characteristic relaxation time = 7 s), allowing for interfacial welding and postprinting functionalization. Modulation of the cross-linking density postprinting is enabled by selective hydrolysis of the boronate esters to generate networks with swelling capacities tunable from 1.3 to 3.3.
doi_str_mv	10.1021/acsmacrolett.1c00257
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source	American Chemical Society:Jisc Collections:American Chemical Society Read & Publish Agreement 2022-2024 (Reading list)
subjects	Esters Materials Testing Printing, Three-Dimensional Resins, Plant
title	Chemical and Mechanical Tunability of 3D-Printed Dynamic Covalent Networks Based on Boronate Esters
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